DE4312386C1 - Fuse and ignition unit for small bomb - has turbine through which air flows arranged on cross-axial movable slider and with permanent magnets in its vanes used to charge ignition capacitor. - Google Patents

Abstract

The unit has an air powered turbine (38) on a slider (10) carrying at least one permanent magnet (44) and at least one coil (50,50') arranged on the slider. A voltage is induced, on rotation of the turbine, through the permanent magnet, which charges an ignition capacitor (54). An ignition rod (16) is operable by a contact trigger (28) connected to the ignition capacitor and a detonator (26). If the bomb does not trigger on impact, the capacitor charge is used for triggering. The two coils are arranged diagonally opposite one another underneath the turbine. The turbine has several vanes (42) with permanent magnets on them. ADVANTAGE - Increased probability that bomb is actuated. If bomb does not trigger on impact, later unintentional triggering is prevented, as capacitor loses its charge.

Description

The present invention relates to a backup and Ignition unit for a bombed according to the generic concept of Claim 1.

Bomblets are from a top floor, such as B. a rocket ejected daughter bullets, which are usually on one Float the stabilization band down to a target. As long as that Bomblett floats down, becomes a over the stabilization band Tension is applied to a firing pin. Only when the through when hitting a target on the stabilization band the force exerted by the firing needle wears off, the firing needle - driven by a spring - via a tapping primer Detonate explosive devices. It has been shown that in cases where the bomblet instead of on a hard target on soft ground occurs, the ignition is no longer guaranteed, so that at a later unintended movement the ignition of the unlocked bomblets can take place.

It is the object of the present invention, a backup and Ignition unit for a bomblet specify that with increased Safety ensures the ignition and in the event that the Ignition should not occur on impact, a later one  Triggering by moving the bomblet largely prevented.

This problem is solved according to the characteristic ones Features of claim 1. Further advantageous Ausge Events of the facility are the dependent claims removable.

In this context, it should be noted that it is principally for example from US-A-2 926 611, by a a propeller driven generator to generate one Use ignition voltage on a bomb or rocket.

Using one of the figures in the accompanying drawing Darge illustrated embodiment in the following are the backup and Ignition unit according to the present invention closer explained. Show it:

. Figure 1 shows the principle of a mechanical fuse Bomblettzünders;

Figure 2 is a formed according to the invention a backup and slide firing unit in a side view. and

Fig. 3 shows the same slide in a plan view.

Referring to FIG. 1 engages in a blind hole 12 of a slider 10, a safety pin 14 a. An ignition needle 16 is installed in the safety pin 14 so as to be displaceable in the axial direction. The firing needle 16 is biased by a compression spring 18 , which is supported between the lugs on the safety pin 14 and the firing needle 16 .

In the securing, the slide 10 is secured against transverse axial movement by the safety pin 14 engaging in the blind hole 12 and the ignition needle 16 is also pressed against the bottom of the blind bore 12 by the compression spring 18 .

After the ejection of the bomblet (not shown) from a mother projectile, the firing needle 16 is pulled into the safety pin 14 against the force of the compression spring 18 by the tension of a stabilizing band 20 , which acts on the firing needle 16 via a tension bracket 22 . At the same time, the safety pin 14 is moved upward by rotation in a thread 24 and releases the slide 10 after approximately two turns.

The firing pin 16 remains drawn in until the train on the release band 20 subsides, which is the case when it is opened. A tapping primer, not shown, arranged in the slide 10 is ignited by the firing needle 16 when the impact on the firing needle 16 disappears upon impact, so that the compression spring 18 can move the firing needle 16 downward.

This concept has the advantage that the tapping function under  all surcharge conditions regardless of the occurring Delay is so that the ignition function safety is essential is increased.

To further improve the detonator function, it is now provided according to FIGS . 2 and 3 that the tapping detonator is replaced by an integrated electrical detonator 26 (stratified primer). This electrical detonator 26 consists of a tantalum bridge 28 at the bottom of a blind hole 30 in the slide 10 , which is filled with pyrotechnic material 32 . When the safety pin 14 is removed from the blind hole 12 , the slide 10 is displaced transversely axially by a spring engaging in a spring channel 34 , not shown, until the ignition pin 16 lies over the tantalum bridge 28 .

The energy supply for the tantalum bridge 28 is ensured as follows:
To a fixed in the slider 10 axle 36, a turbine is mounted for rotation 38, the rotor consists of a disc-shaped plastic body 40 having circumferentially radially extending inclined wings 42, wherein in the wings 42 of permanent magnets 44 are inserted. After unlocking the slide 10 , it is pushed transversely axially outward, so that the turbine 38 is flown by the air when the bomblet floats down. To improve the inflow effect, the slide 10 is also provided with recesses 46 , 48 , 48 ', so that in these areas the wings 42 are above the slide 10 .

Under the turbine 38 are arranged diagonally on a diameter two coils 50 , 50 'in the area of the wing 42 , in each of which a voltage is induced by the permanent magnets 44 moving past. Both coils 50 , 50 'are connected by conductor tracks 52 , 52 ' to an ignition capacitor 54 , a decoupling and rectifying diode 56 being arranged in the charging current path of the ignition capacitor 54 . Via further conductor tracks 58 , 58 ', the ignition capacitor 54 is connected to a trigger in the form of the tantalum bridge 28 , which can be short-circuited by the ignition needle 16 .

The slide 10 is designed as a steel substrate, on which the conductor tracks 52 , 52 'and 58 , 58 ' are printed.

The ignition circuit consists of the ignition capacitor 54 and the contact 28 connected via the conductor tracks 58 and 58 ', which is actuated by the ignition needle 16 . It is assumed here that if the ignition contact actuation fails, the ignition capacitor 54 has discharged after some time, so that the system is inert. Ignition by moving the bomblet can be excluded with certainty in the inert state.

Furthermore, a circuit (not shown here) can be provided, which ignites the detonator 26 when the ignition capacitor voltage drops below a defined value.

Claims (6)

1.Safety and ignition unit for a bomblet with a slide which can be moved transversely axially by a spring, which is held in the securing position by a safety pin which engages in a blind hole of the slide and which is released when the bomblet is ejected by the force exerted on the safety pin and into an ignition position is displaceable, in which a spring-tensioned ignition needle arranged in the safety pin actuates a detonator in the slide, characterized by a turbine ( 38 ) which is arranged on the slide ( 10 ) and is flown by the air and has at least one permanent magnet ( 44 ). carries and at least one on the slide ( 10 ) arranged coil ( 50 , 50 '), in which a voltage is induced in the rotating turbine by the at least one permanent magnet, with which an ignition capacitor ( 54 ) is charged and by an electrical contact trigger ( 28 ) connected to the ignition capacitor ( 54 ) and the detonator ( 26 ) is connected and can be actuated by the ignition needle ( 16 ). 2. Unit according to claim 1, characterized by the arrangement of two coils ( 50 , 50 ') diagonally opposite under the turbine ( 38 ), the turbine ( 38 ) having a plurality of vanes ( 42 ) arranged permanent magnets ( 44 ). 3. Unit according to claim 2, characterized in that the coils ( 50 , 50 ') are electrically connected to one another and are connected to the ignition capacitor ( 54 ) via a diode ( 56 ). 4. Unit according to one of claims 1 to 3, characterized in that the slide ( 10 ) consists of a steel substrate with printed conductor tracks ( 52 , 52 ', 58 , 58 '). 5. Unit according to claim 4, characterized by recesses ( 46 , 48 , 48 ') on the slide ( 10 ) to allow an inflow onto the blades ( 42 ) of the turbine ( 38 ). 6. Unit according to claim 1, characterized by the specification of a discharge time constant for the ignition capacitor ( 54 ).